              TABLE I                                                     ______________________________________                                    % Transmittance (±0.5%)                                                               Chemical Solution                                          ______________________________________                                    100            sodium bicarbonate                                         100            sodium chloride                                            100            urea (carbamide)                                           97             sodium dodecyl sulfate                                     95             polyethylene glycol                                        94             isopropyl alcohol (70%)                                    94             ethyl alcohol (100%)                                       93             2-amino-2-(hydroxymethyl)-1,3-                                            propanediol                                                93             triethanolamine HCl                                        92             myristytrimethylammonium bromide                           81             lauric acid*                                               79             myristic acid*                                             65             methyl alcohol (70%)                                       30             formamide*                                                 24             benzalkonium chloride(1:1000)                              ______________________________________

The following solutions showed a % Transmittance of less than 1.0%.

sodium hypochlorite

liquid phenol*

p-tert-amylphenol*

Solutions determined to have a relatively high percent transmittance to ultraviolet light (%T greater than 20%) were employed in the sterilization method of the present invention to determine their effectiveness therein. The test organism used was Bacillus Subtilis (ATCC No. 19659), and the AOAC method previously identified herein was used for growing and harvesting the spores. Approximately 4 ml of a working suspension of the spores (approximately 1×10⁷ spores/ml in Ringers solution) was combined with approximately 36 ml of the liquid surfactant in a sterile 50 ml beaker which, in turn, was suspended in an ultrasonic bath equipped with an ultraviolet light above the bath in a manner which will be described presently. The ultrasonic bath was a Bransonic 52 (Branson-Smith Kline Co. 50/60 Hz, 117 volts, 240 watts) and the ultraviolet lamp employed was a General Electric G2578, 25 watts, germicidal, 60 Hz, 115 volts. The samples were simultaneously exposed to ultrasonic radiation at 52 kilohertz, 240 watts and ultraviolet radiation at 2537 Å wavelength and 300 microwatts/cm². Samples when there withdrawn after definite intervals, such as 3, 6, 9, 12, 15, 30 and 60 minutes and plated after serial ten-fold dilutions. The cultures were incubated aerobicly at 37° C. for 24 hours before counting. The survival counts for each exposure time to each chemical solution were then plotted on a graph. These deactivation curves showed that most of these chemical solutions were capable of achieving sterilization when used with the method of the present invention, however, some of the solutions were more efficient than others. The more transparent solutions (high %T) tended to be more efficient (quicker sterilization) than those which were less transparent in this test against naked hydrated spores.

EXAMPLE III

In order to better evaluate the solutions in a more realistic situation, the AOAC test utilizing vacuum dried spores on pennycylinders and silk suture loops was used. The conditions used in this test were the same as those in Example II except the 50 ml. beakers contained 40 ml. of the solution being tested and then 5 suture loops or 5 pennycylinders were added, the device was turned on, and then the sutures or pennycylinders were withdrawn and cultured after differing time intervals (i.e. 1, 2, 3, 4, 5, etc. minutes). The above procedure was repeated twenty times for each chemical solution. The other factor in the experimental conditions which was changed from the conditions used in the previous example was that the intensity of the ultraviolet radiation had been increased to 2,000 microwatts/cm². An aqueous solution of sodium dodecyl sulfate (sodium lauryl sulfate) and carbamide (urea) at 1-3% dry weight each was found to sterilize in less than three minutes using AOAC techniques.

While the above mentioned solution was found to be the most efficient of the solutions tested, a number of other solutions were found to be effective and achieve sterilization when used in the mehod of the present invention. These solutions included sodium dodecyl sulfate (sodium lauryl sulfate) alone in aqueous solution, carbamide (urea) alone in aqueous solution, aqueous solutions of surface active quaternary ammonium compounds, distilled water, saline solution, alcohols (isopropyl, ethyl, methyl), polyethylene glycol, organic acids (acetic, lauric, and myristic), sodium silicate, and sodium bicarbonate. These results indicate that the key factor with respect to the liquid is that it has a relatively high transparency in the ultraviolet region of the spectrum. A second important factor that increases efficiency and reliability of an effective solution is its ability to act as a wetting agent to help reduce surface tension and thus make for more efficient and reliable cleaning action.

FIGS. 1 and 2 illustrate apparatus according to the present invention for carrying out the method described herein. An ultrasonic bath generally designated 10 has a hollowrectangular body portion 12 with an open top which is closed by a cover orlid 14 hinged tobody 12 along one edge in a conventional manner. Ahandle 16 onlid 14 facilitates manual opening and closing thereof. The front surface oflid 14 is provided with awindow 18 of glass which permits viewing of the interior of the apparatus. The glass is of the commonly available window pane type which is known to have a low transmittance to ultraviolet light. The opening inbody 12 is bordered by aperipheral flange 20 which cooperates with alip 22 oncover 14 to prevent escape of ultraviolet radiation from the apparatus interior whencover 14 is closed.

A tray orholder 24 rests within the interior region ofbody 12 on the bottom surface thereof for holdingobjects 26 to be sterilized. At least oneultraviolet lamp 30 is provided and electrically connected at opposite ends to a pair ofconventional sockets 32 mechanically fixed to opposed inner surfaces ofcover 14.Sockets 32 are connected electrically byconductors 34 to a standardballast transformer component 36 which, in turn, is connected to an electrical supply circuit (not shown) in theultrasonic bath 10 having appropriate external connection by a conductor and plug to a standard electrical outlet. The supply of electrical power tobath 10 is controlled by a conventional on-off switch.

Theultrasonic bath 10 can be a Bransonic 52--Branson (Smith Kline, 50/60 Hz, 117 volts, 240 watts) with the cover modified to carryultraviolet lamp 30 which can be a General Electric tube type lamp G2578, 25 watts, germicidal, 60 Hz, 115 volts. The inside ofbody 12 is of stainless steel or similar metal which is reflective to ultraviolet light. The inside ofcover 14 preferably is lined or coated with alayer 44 of ultraviolet light-reflecting material, for example a suitable metal. While oneultraviolet lamp 30 is shown for convenience in illustration, several lamps can be installed incover 14 in spaced, side-by-side relation. The apparatus can be provided with a safety switch (not shown) electrically in series betweenlamp 30 and the power supply and operated in response to opening and closing oflid 14 such that the switch is open when the lid is open and closed only when the lid is closed withflange 20 in contact withlip 22.

In operation,tray 24 carrying theobjects 26 to be disinfected and/or sterilized, for example medical or dental instruments, are placed in the interior region ofapparatus 10 as shown and the liquid is introduced tobody 12 to alevel 46 covering the objects to be sterilized.Lid 14 is closed and the apparatus then is turned on resulting in simultaneous exposure of theobjects 26 to ultrasonic and ultraviolet radiation. The apparatus would be provided with a timer (not shown) to indicate the duration of treatment to the user, and an appropriate timer control could be associated with the power supply to turn the apparatus off after a selected treatment time. Preferably, the safety switch previously described operates to turn off only the ultraviolet lamp iflid 14 is opened to avoid ultraviolet exposure to personnel using the apparatus and still allow the apparatus to operate if only ultrasonic cleaning is desired. Theapparatus 10 should be constructed to minimize the required depth of the liquid surfactant inbody 12 and also to minimize the distance betweenultraviolet lamp 30 and objects 26 whenlid 14 is closed.

In some situations, several units ofapparatus 10 can be employed, the first bath being used with a cleaning solution to effectively pre-clean the objects before they enter a second bath providing the combination of liquid and ultraviolet and ultrasonic radiation. A third unit could be included to serve as a drying chamber. Transfer of objects from unit to unit could be done manually or in an automated manner. In fields of use where specific objects are to be sterilized, for example a dental instrument tray set up or hospital surgical instruments, thebody 12 of the apparatus could be constructed so as to accept a standardized tray which would hold the objects and have a porous bottom to allow for drainage after sterilization. This entire tray then could be carried as an instrument tray or stored in a sterile cabinet until needed. The apparatus can be equipped with a heater and thermometer for operation at higher temperatures if desired.

It is therefore apparent that the present invention accomplishes its intended objects. While an embodiment of the present invention has been described in detail, this is for the purpose of illustration, not limitation.